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Revision: Sun, Stars (and Planets)See web slides of Dr Clements for Planets revision
Juliet Pickering Office: Huxley 706
Office hour (Pickering):Office hour (Pickering):
Thursday 22nd May 12Thursday 22nd May 12--1 pm1 pm
The Sun: its structure and energy generation
Stars: putting the Sun into context
Outline overview of first part of the course
Stars: putting the Sun into context
Solar structure and energy generation:
What is a star?
Stellar structure equationsEstimates of ρ, P, T etc
energy generation – nuclear burningenergy generation – nuclear burning
convection vs radiation
Interior structure
Timescales (thermal, dynamical)
Solar Atmosphere , Solar activitySolar spectrum
Mass continuity
Hydrostatic equilibrium
Energy generationEnergy generation
Equation of state
You need to know this!
Solar atmosphere
• Photosphere• Chromosphere• Transition region• Corona• Solar wind
Magnetic Activity
Intensity vs wavelength, Planck curves for blackbodies at a range of different temperatures
500 1000 2000
Wavelength /nm
500 1000 1500Wavelength
Stars: putting the Sun into context –
supergiants
Red giants
Main sequence
White dwarfs
r1 r2m1
r
• m2O••
Physical parameters and their measurement: egsL,
magnitude – absolute and apparent distance (parsec pc, light years, AU)
parallax, proper motionparallax, proper motioneffective T, colour indexageradius, mass, composition (stellar spectrum,
spectral type, spectral classification, opacity)Units (arc sec, parsec, light year, solar units etc)
Spectral classification of stars
Type Colour Teff (K) Main characteristics
Examples
O Blue > 25000 He+ lines; strong UV
Mintaka(δ Orionis)
B Blue-white 11000 – 25000 Neutral He lines Rigel, Spica
A White 7500 – 11000 Strong H lines Sirius, Vega
F Yellow-white 6000 – 7500 Weak metal lines Procyon
G Yellow 5000 – 6000 Solar-like spectrum
Sun, Capella
K Orange 3500 – 5000 Metal lines dominate
Arcturus, Aldebaran
M Red < 3500 Molecular bands noticeable
Betelgeuse, Antares
Each class also divided into 10 subdivisions, so e.g. …, B8, B9, A0, A1, A2, … A9, F0, F1, …
0 being hottest, so F9 and G0 are very similar stars
HR diagram and stellar evolution
• dependence on stellar mass,• types of stars• time spent in different stages• explanations • explanations • Evolutionary tracks• homologous series,• Age of star clusters
most luminous supergiants
less luminous supergiants
luminous giants
normal giants
subgiants
Mv
HR diagrams
O B A F G K M
subgiants
dwarfs (main-sequence
stars)
L ∝∝∝∝ M 4BB--VV
supergiantssupergiants
Red giantsRed giants
Main sequenceMain sequence
White dwarfsWhite dwarfs
PleiadesHomology transformationConsider set of stars of homogeneous composition, burning hydrogen.
Stars differ only because of their mass.
ρc ∝ M / R3
Pc ∝ M2/ R4
Tc ∝ M / R etc etc
Derived many relations, egs:
So massive stars (at top of main sequence) exhaust their hydrogen quickest -- explains turn -off point in turn -off point in clusters.
Estimating cluster age
→→
Use a
→→
Use a relevant M-L relation:
Or even simpler : see problem sheet 3 for rough estimate
DF
G
Stellar evolutionary tracks on an HR diagram
A
BCE
H
• Binary Stars
-Visual-Spectroscopic-Eclipsing
r1 r2m1
r
• m2O
••
Revision: Sun, Stars (and Planets)See web slides of Dr Clements for Planets revision
Juliet Pickering Office: Huxley 706
Office hours (Pickering):Office hours (Pickering):
Thursday 22nd May 12Thursday 22nd May 12--1 pm1 pm
Good luck !Good luck !
Any Any questions? questions?
Sun, Stars & PlanetsRevision Lecture
Dave Clements & Juliet Pickering
Thursday, 8 May 14
Overview
• The Exam & Exam advice
• Stars Summary
• Planets Summary
• Questions
Thursday, 8 May 14
The Exam
• Format same as previous years:
• Section A: compulsory [40 marks]
• Will include a question on stars & a question on planets
• Section B
• Choose 2 questions out of 4 [30 marks each]
• Will include an ‘essay’ type question
Thursday, 8 May 14
What you are Given
• List of constants
• Equations of Stellar structure
Thursday, 8 May 14
Fundamental physical constants
a radiation density constant 7.6 ⇥ 10�16 J m�1 K�4
c speed of light 3.0 ⇥ 108 m s�1
G Gravitational constant 6.7 ⇥ 10�11 N m2 kg�2
h Planck’s constant 6.6 ⇥ 10�34 J sk Boltzmann’s constant 1.4 ⇥ 10�23 J K�1
e electron charge 1.6 ⇥ 10�19 Cme mass of electron 9.1 ⇥ 10�31 kgmH mass of hydrogen atom 1.7 ⇥ 10�27 kgNA Avogadro’s number 6.0 ⇥ 1023 mol�1
� Stefan-Boltzmann constant 5.7 ⇥ 10�8 W m�2 K�4
✏0 permittivity of free space 8.9 ⇥ 10�12 F m�1
µ0 permeability of free space 4⇡ ⇥ 10�7 H m�1
R Gas constant 8.3 ⇥ 103 J K�1 kg�1
Astrophysical quantities
L� solar luminosity 3.8 ⇥ 1026 WM� solar mass 2.0 ⇥ 1030 kgR� solar radius 7.0 ⇥ 108 mTeff� effective temperature of Sun 5780 KAU astronomical unit 1.5 ⇥ 1011 mpc parsec 3.1 ⇥ 1016 m
Equations of Stellar Structure
dmdr
= 4⇡ r2 ⇢
dPdr
= � Gm⇢r2
dTdr
= � 3 ⇢ L16⇡ a c r2 T3 if heat transport is radiative
dTdr
= 1 � 1�
!TP
dPdr
if heat transport is convective
dLdr
= 4⇡ r2 ⇢ ✏
2013/PO2.1 2
Thursday, 8 May 14
Fundamental physical constants
a radiation density constant 7.6 ⇥ 10�16 J m�1 K�4
c speed of light 3.0 ⇥ 108 m s�1
G Gravitational constant 6.7 ⇥ 10�11 N m2 kg�2
h Planck’s constant 6.6 ⇥ 10�34 J sk Boltzmann’s constant 1.4 ⇥ 10�23 J K�1
e electron charge 1.6 ⇥ 10�19 Cme mass of electron 9.1 ⇥ 10�31 kgmH mass of hydrogen atom 1.7 ⇥ 10�27 kgNA Avogadro’s number 6.0 ⇥ 1023 mol�1
� Stefan-Boltzmann constant 5.7 ⇥ 10�8 W m�2 K�4
✏0 permittivity of free space 8.9 ⇥ 10�12 F m�1
µ0 permeability of free space 4⇡ ⇥ 10�7 H m�1
R Gas constant 8.3 ⇥ 103 J K�1 kg�1
Astrophysical quantities
L� solar luminosity 3.8 ⇥ 1026 WM� solar mass 2.0 ⇥ 1030 kgR� solar radius 7.0 ⇥ 108 mTeff� effective temperature of Sun 5780 KAU astronomical unit 1.5 ⇥ 1011 mpc parsec 3.1 ⇥ 1016 m
Equations of Stellar Structure
dmdr
= 4⇡ r2 ⇢
dPdr
= � Gm⇢r2
dTdr
= � 3 ⇢ L16⇡ a c r2 T3 if heat transport is radiative
dTdr
= 1 � 1�
!TP
dPdr
if heat transport is convective
dLdr
= 4⇡ r2 ⇢ ✏
2013/PO2.1 2Thursday, 8 May 14
Exam Advice: 1
• Read all questions before choosing which to do
• Read them carefully: eg. sketch does not mean plot exactly, estimate does not mean make a precise calculation
• Check units: astronomical units are not SI
• angles - arcsec vs. radians
• distances - m, AU, pc
Thursday, 8 May 14
Exam Advice: 2
• Remember: one answer book for each question
• Write legibly!!!!
• Give intermediate steps so we can follow what you’re doing and give credit if things go wrong half way
• If you reach an answer you know is wrong but can’t fix it, tell us it is wrong and why it is wrong
Thursday, 8 May 14
Resources• On Blackboard
• Lecture notes
• Problem sheets
• Handouts
• Slides from lectures
• Past papers
• Office hours
• Come and see us or email us!
• But not at the last minute ie. weekend before the exam
Thursday, 8 May 14
A storm onSaturn
Thursday, 8 May 14
Solar System: Key Points
• Structure of the Solar System: Planets, Ecliptic, Nebular Hypothesis
• Kepler’s Laws
• 1)The orbit of a planet forms an ellipse with the Sun at one focus
• 2)The Sun-planet vector sweeps out equal areas in equal time
• 3)The square of the orbital period of the planet is proportional to the cube of the orbit’s semi-major axis
• Know & explain all 3
• Show 3rd law in the context of a circular orbit
Thursday, 8 May 14
Planets: Key Points• Terrestrial Planets:
• atmospheric & interior structure
• cooling & heating
• shaping of surfaces
• no-atmosphere temperature, Greenhouse Effect & Carbon cycle
• Gas Giants:
• structure & atmospheres
• ring systems and moons
• Roche limit
• Asteroids, KBOs and Comets
• Orbital resonances & tidal locking
• Comet reservoirs (Oort cloud & KBOs) and implications for comets
Thursday, 8 May 14
Exoplanets: Key Points• Detection methods:
• astrometry
• transits
• radial velocities
• equations simplified version of binaries with Mp << Ms
• appreciate selection effects, explain quantities being measured
• Exoplanet characteristics
• not rare, systems being found, range of eccentricities, many short-period planets including hot Jupiters
• Possibility of life outside the Solar System
• Habitable zone, Drake Equation & Fermi Paradox
Thursday, 8 May 14
Thursday, 8 May 14
